Dust separator



March 9,1948. v D. DALIN DUsT-sEPARAToR Filed sept. 5o', 1943 2 Sheets-Sheet l March 9, 1948. D. DALIN DUST SEPARATOR Filed sept. zo, 1945 2 Sheets-Sheet, 2

Patented Mar. 9, 1948 UNITED .STATES "Sections 1 and 3, Public Law 4{390,gl1-1gust,8.,j-1941i f Patentexpirs September', 1962-v f s l sciame (ci. 1583-32) This .invention relates to improvements in dust separators -andi refers more particularly tolseparators 'designed Iorthe purposeiofiseparating solid particles from hot gases.E The inventioni applies especially to such knownidevioes,'where the gases are caused to flow around-the inside of a drum which may be round; spiral-shaped -or of lany othersuitable shape and f Wherev the'.v gases iare -forced tofollowithe 'shapefof ythe drurrrpbutfinV which the' gasescontinually change. their direction of how. Openings are .usuallyplaced in'the peripheral wallof this drum; Qrseparator cha'mberV so positioned thatr when vthe gas passes these openings the solid particles entrained in 1 theses vare,thrown out through Said -.0per11 ne s by centril line 3--3 in Figuren;

This invention finds particularapplication@ cases where the gases arevof-.such.hightemperaseparators are ordinarily. made, will be-damaged bythe high temperatureoithe gases. t

To this end itis an object-ofl this inventiomto vprovide a novellmanner of protecting the 'Walls of the separator and all parts "thereoforjdinarily 525 stinanath'er object off this invention is toys@ dispose the uid cooledljiiils'lyoijducts/as fto'fde'- iine the discharge port through which the separated Lsolid particles enter the: collecting hopper or compartment: 'l J A further objectof'fthis'inrentlon 4is t"so"lr 040 range the edges ofthe-dischargfeport for thesep- -arated solids with relation tothe iiowof ythe gases as to facilitate the discharge `of the solids. With the aboveand other objects in View; which -will appear as'the description'proceedspthis'in 5451111 ventio'n residesv inthenovelfconstruction, coxnbination and arrangementfofwparts substantially as hereinafter` Jdescribed'; and' more' particularly n"301i dened-with the best modes'iso far' devisedl for? the practical applicationy ofiv the: principles thereof, land 1n which: i zA o IFigure 1 `is aiv'er-tical sectional vieWthrough-a s 5 Vcentrifugal type. fdustfse'paratorillustrating one embodiment of this:'inye'ntion,.r said-.View` being ftak'en on the planelofthev liner l--I =of Figure 2; -f.-Figure'.2 .is :a ,'verticalisectional view through '.the separator shown in Figurel,` said view being 1z0 `taken on the planelof thelline 2-2 Yof Figurel;

L3 Figuregis a; sideielevationfwith parts broken fawayand in section; of 'a"dustseparatorgof the foy@ionetypairi11usncating another form of lthis iin'- vention, said view 'being taken onthe plane of the Figure 4 is ani encli viewof thef s'eparatorshown lil'iFlg'llIelSLl cg s l s 5 Fig-ureV 571s a..detailsectional-view taken on the plane of the vlir'ie'SLE -in Figure'v3;`-

0 Figure 6 is afragmntary top View of the-par- 'ticularfs'tructureshown in' Figure ,5; and

H Pfrrng ,90W Particularly @the :accompanyling drawings, inA :which s like `numerals "indicate like j parts; the; numeral 5 designates generally La '.fspiralfshapefdfgdiiuser"housing or chamber hgv'l- .ingia'n' 'inlet `fr; air and' eases `Winch 'maybe :solid particles: of extraneous inat- Ll'lfhe bottoni Loi thel, diffuser "housing or (chamber opens; to a colli-Seting hopper or` cornpartirent Ma. which the selig' raref .Separated 'fo'm the air or gases accunriulhate.V This collecting. hopper QrqompertmentfisPreferably funnel .shaped and ianlcutlet lllrin 'its bottom; v,neutronesby: a damper-l Y. 1 1 1The, rr,1a1;n supprtiriefwalls of th dilfuserphouss Yor amberzasvwel-las theecolleetnehopper may be; Ofiany4 Suitablesmarteria- 1,-L but.. where the separator is tog'A beiused iinconjunctionl with vheat generating devices of. fvarious types', such asblast furnaces,lforgesdsulphiteland sulphate plants for 'stood' that suchechanges?in'.the1precise embodi- "50 Vpapelllllp"IlflallllfaMilliers,iCeIlflenmills,Tiri/ing ment ofA the hereindescribe'diinvention' mayebe made as: comewithinthescopemf the' claims.-Vv

' f .The accompanying 'drawings illustrate-'several complete: examples of.- l'iedphysical embodiment ofi-masonry construction; L ,is .z i; i

'mills',;stean1 boilers, and all;v kinds of .hot.`.dust laden'.` gases,;itV` ispref'erable that .these "wallsfbe msnen' instancessar is alsovdesirati t mount of the finveritinicbristructed in" accordance-with F66 r`tllebliiuser housing' -directlyiadjacent; to'one Wall energica I2 of the combustion chamber or other source from which the gases issue.

It is desirable to have the inside walls of the separator lined, but the extremely hot gases to be handled makes ordinary lining expedients unsatisfactory. Thus, the inner Walls of the separator contacted by the hot gases are covered by layers or banks offluid cooled tubes or ducts.

One bank or set I3 of these fluid cooled tubes consists of coils shaped to overlie the peripheral housing. While this inward protrusion can be formed of fluid cooled coils like the conical outlet passage 25, it is preferably formed of plate construction, being built up as a unit and inserted into the wall 26 through a hole 28 therein.

The protrusion 21 is hollow and has a partition 29 extending down the center thereof joined to its head wall 39 but spaced from the apex of the protrusion. Hence, a cooling medium entering a wall I4 of the diffuser housing or chamber op-` posite the inlet opening, extending solidly over the entire surface thereof.

As shown, these coils begin at the inlet 6 and follow the wall I4 to its juncture withY the collecting hopper or compartment 9 where they continue with the same curvature a substantial dis-V tance therebeyond to terminate as at I on a` transverse line spaced a short distance'from a vertical plane passing'through the axis of the outlet 1 and the collecting hopper 9. At this point I5 the coils reverse themselves and continue back to the inlet where they have another hairpin turn to continue back to the point I5,

serpentine fashion back and forth, until the entire area of the wall I4 is covered.

The inlet of the bank of coils I3 may be through the top of the diffuser housing as indicated by the center line I6. The opposite end of this bank of coils is connected by a bridging duct indicated by the center line I1, with a bank of coils I8 which overlies the bottom wall of the inlet 6 and connects with the arched bank of coils I9 covering the adjacent near curved wall 29 of the diffuser housing or chamber.

The bank of coils I3, like the coils I3, terminates as at I5 on a transverse line spaced a short distance from the vertical plane passing through the axis of the outlet 1 `and through the collecting hopper 9. These termini I5 and I5 of the respective coil banks I3 and I9 thus define the discharge port 2I through which the solid particles entrained in the hot gases leave the diffuser housing or chamber to enter the collecting hopper or compartment 9.

The flat side walls of the diiuser housing are also covered by banks of fluid cooled tubes indicated by the center lines 22. The specic arrangement of the coils is, of course, subject to modification and the arrangement shown is but illustrative, it being important only that the coils be compactly arranged to adequately cover and protect the masonry walls of the diffuser housing or chamber which are directly contacted by the hot gases.

The collecting hopper or compartment 9 preferably has its Walls lined with plate 23 of which the outlet I0 is formed, but this plate lining is preferably protected by fluid cooled coils indicated by the center lines 24.

The outlet 1 is defined by a conically spiralV coil 25 which projects a substantial distance into the interior of the diffuser housing or chamber as shown in Figure 2. This formation produces a baille to deflect solid particles entrained by the hot gases from passing out through the outlet I.

To further assure against the passage of solid particles out with the discharging gases, the opposite side wall 26 of the diffuser housing or chamber has an inwardly directed conical protrusion 21 mounted thereon. This protrusion is on the axis of the outlet 1 and causes such solid particles as have a tendency to follow along with the gas stream toward the outlet 1 to be thrown outwardly toward the periphery of the diffuser port 3| in the head wall and leaving a port 32 therein is caused to circulate through the conical protrusion and keep the same cool.

In the dust separator illustrated in Figures 3 and 4 the dust laden or burdened air enters an inlet 33 disposed tangentially with respect to a substantially cylindrical or slightly conical diffuser housing 34. A cylindrical duct 35 passing through and secured to an end wall 36 of the housing with the inner end thereof projecting a substantial distance into the housing provides the outlet.

Beneath the diffuser housing is a dust collecting hopper 31 connected with the interior of the diffuser housing by an elongated'slit 38. This slit 38, as clearly shown in Figures 4 and 5, has its edges offset radially with its edge 39 which is nearest the inlet 33 from the standpoint of direction of flow, disposed farther outward than the opposite edge 40. This arrangement facilitates the discharge of the solid particles into the collecting hopper 31.

The entire internal surface of the diffuser housing is covered by coils of fluid cooled tubes 4I which preferably extend into the conical end 42 of the diffuser housing. The inlet 33 is protected by coils 43 and the outlet duct 35 is protected by fluid cooled coils 44 disposed on the inside and outside thereof.

Attention is directed to the fact that the coils 4I which lie in the substantially cylindrical or gently conical wall of the diffuser housing chamber 34 terminate adjacent to the edges 39` and 49 of the slit 38. In fact, it is the termini of these coils at these edges which dei-lne the actual slit opening 38.

In that embodiment of the invention illustrated Vin Figure '7 the separator chamber or diffuser housing is formed as a double curved tube 45 of progressively smaller cross section. The dust laden air or gas enters this tube-through the i-nlet opening 46 and leaves the same through the outlet opening 41. Directly after the first curve the lower portion of the tube has a discharge port 48 through which the solid particles pass into a collecting chamber 49.

In passing the discharge port 48 the gas or air changes direction with the curvature of the pipe 45, escaping through the outlet 41, while the solid particles due to their inertia continue in a line tangent to the curvature of the pipe wall immediately -ahead of the port 48 to pass out through this port.

To protect the inner walls of the pipe 45 as well as the collecting chamber 49 fluid cooled coils 59 cover these walls. VThese coils can be arranged in any desired manner, either lengthwise or crosswise with the relation to the direction of gas now.

From the foregoing description, taken in connection with the accompanying drawings, it will be readily apparent to those skilled in the art that this invention provides a dust separator especially well adapted for use in installations where the gases to be handled are extremely hot greener and that thisA Vinileation.i provides ,a practical solution for the problem thus' presented;

Having described myinvention what I claim as new-anddesire to protect by Letters Patent is:

1. AA centrifugal type dust' separator forseparati-ng solid particles from. extremely-hot gases Comprising: 1a. chamber having.- inletffor the het burdened-gases;@dnner riftiifejdhburdened particles separated from :the gasessaid chamber being 'shaped so as to impartabrupt changes in the direction of now of4 thegases therethrough so that the solid particles enutained bfyr't are separateditherefrom' b'YL' rfi moving particles;I anda substantif@ protective coveringfonthe'i particlesseparated from tlnlggases, said cl'iamberA brupt changesiin being shaped. so as to impa'ET the 'di'rectionv o'fnowofthe y so' that' the `^"s`oli'dp'articlesen by the gases are" separatedtherefrom'by ntheihertia of the moving Solidparticles",f "and aprdte'ctivecovering for the inner wallsofthesepartor comprising a plurality ofclbsely..djactserpentine coils disposed to provide an imperforate liningfor the stherethrough Walls'oftheseparator whi' the .overlieso'as'to 3. A centrifugal type dust separator for separating solid particles from extremely hot gases comprising: a chamber having an inlet for the hot burdened gases, an outlet for the unburdened gases, and a collecting compartment for the solid particles separated from the gases, said chamber being shaped so as to impart abrupt changes in the direction of ilow of the gases therethrough so that the solid particles" entrained by the gases are separated therefromlby the inertia of the moving solid particles; and banks of cooling coils providing a substantiallyl imperforate lining for the walls of the separator chamber and forming the lip of the mouth to the collecting compartment over which the solid particles slide to reach the collecting compartment. said coils being adapted to have a coolant circulated therethrough.

4. A centrifugal type dust separator for separating solid particles from extremely hot gases comprising: a chamber having a substantially circular body portion with an inlet leading tangentially thereto and an outlet leading substantially axially therefrom so.that hot gases having solid particles entrained therein and entering the tangential inlet swirl around the outlet before reaching the same, whereby the solid particles entrained in the gases are thrown outwardly by centrifugal force; banks of fluid cooled coils solidly covering the inner surfaces of said chamber, its inlet and outlet, to preclude contact of the extremely hot gases with the walls of the chamber, the coils covering the circular walls of the chamber being interrupted at the bottom of the chamber to provide an outlet for the solid particles separated from the hot gases; and a I5 imperforate sides to cause the hot burdened gases collecting compartmentfbeneatn 's aidf opening to receive thesolid particles separated` from the gases-. t* Y,

5. A centrifugal Atype dust-separator for separating solid particles-from extremely hot gases comprising: a substantiallycylindrical like chamber'having an inlet;opening'ctangentially thereto` through which 'burdend" M Y the chamber, andV anvv outlet substantially e'xally dis-l posed and passing Athroughfone side wall of the chamber; substantially solidvtbanks-of uid cooled coilseoverlying the curvedywallsfof thechamber` to completelycoyenand protect'the same, one bank-`of saidfcils efigtex'cling continuously from the inlet andtangntillyfollowing the far sideA curved wall of 'the cljiamber `:andterminating at a point near-a vie'rj'ticall plane'passing through the axis of the outlet, lanother bank of said cooling coils completely covering-thejcurved wall of the chamber nearest the inlet from atpoint'fadlailent te the inlet toa-ititfsaecfrlff'tnetmiia# tion ofsaid othepbankoffcliwlse sofas to-deiine a discharge portfr lefbbttombfdthechamber through whicls "d'particles separated from the gases pass; andi? 0lleitigHopper?beneathsaid discharge port-t reV ive the" particles.

6.v Acentrifugalat `fforfsep arating solid"particles*Iroinxtremelyf l'gase'sf' comprisingi Aatsubstantially*cylindrical li "hanff ber having an inlet opening tangentiallyftl'ierft'o throughwhieii pertenece chambenla'nd-an 'utl ly posed 'and-i passi" coilsoverlying-th completely cover an' contact by Athe -litg-as extending contiruu A and ftangentiall'yfollowing* lie far silef curved"l wall of the chamber and terminating at a point near a vertical plane passing through the axis of the outlet, another bank of said cooling coils completely covering the curved wall of the chamber nearest the inlet from a point adjacent to the inlet to a point spaced from the termination of said other bank of coils, so as to define a discharge -port at the bottom of the chamber through which solid particles separated from the gases may pass; a collecting hopper beneath said discharge port to receive the solid particles: and a bank of iluid cooled coils completely covering and protecting `the separator.

'7. A centrifugal type dust separator for separating solid particles from extremely hot gases comprising: a substantially cylindrical chamber having an inlet for the hot burdened gases opening tangentially thereto. and an outlet for unburdened gases disposed substantially axially and through one side wall of the chamber; uid cooled ducts providing a substantially imperforate lining for the Walls of the chamber and the inlet to protect the walls thereof from contact with the extremely hot gases, said fluid cooled ducts being interrupted at the bottom of the chamber to define a discharge port for the solid particles separated from the hot gases; and an outwardly expanding conical spiral of cooling coils disposed in the outlet of the chamber with its small diameter end projecting a substantial distance into the chamber and providing a discharge port for the unburdened hot gases having substantially entering the chamber Vto swirl around said coil before entering the outlet passage defined thereby.

8. A centrifugal type dust separator for separating solid particles from extremely hot gases comprising: a substantially cylindrical chamber having an inlet for the hot burdened gases opening tangentially thereto,v and an outlet for unburdened gases disposed substantially axially and through one side wall of the chamber; uid cooled ducts providing a substantially imperforate lining for the walls of the chamber and the inlet to protect the walls thereof from contact with the extremely hot gases, said fluid cooled ducts being interrupted at the bottom of the chamber to dene a discharge port for the solid particles separated disposed in the outlet of the chamber with its small diameter end projecting a substantial distance into the chamber and providing a discharge port for the unburdened hot gases having substantially imperforate sides to cause the hot burdened gases entering the chamber to swirl around said coil before lentering the outlet passage dened thereby; anda substantially conical shaped inward protrusion onrthe side wall of the chamber opposite said coil to cooperate with said coil in insuring separationof the solid particles from the gases before they leave the chamber through the outlet.

9. A centrifugal type dust separator vfor separating solid particles from extremely hot gases comprising: a substantially cylindrical chamber having an inlet for the hot burdened gases open-l ing tangentially thereto, and an outlet for unburdened gases disposed substantially axially and through one side wall of the chamber; iluid cooled ducts providing a substantially imperforate lining for the walls of the chamber and the inlet to S protect the walls thereof-from contact with the extremely hot gases, saidl fluid 'cooled ducts being interrupted at the bottom of the chamber to define a discharge portlfor the solid particles separated from the hot gases; an outwardly expanding conical spiral of uid cooled tightly wrapped coils disposed in the outlet of the chamber with its small diameter end projecting a substantial distance into the chamber and providing a discharge port for the unburdenedhot gases having substantially imperfor'ate sides'to cause the hot burdened gases entering the chamber to swirl around said coil before entering the outlet passage dened'thereby; a substantially conical shaped inward protrusion on the side wall of the chamber opposite said coil to cooperate with said coil in insuring separation of the solid particles from the gases before theyleave the chamber through the outlet, said protrusion being hollow; and means for circulating a coolant therethrough.

DAVID DALIN.

REFERENCES CITED The following references are of record in the fle of this patent:

UNITED STATES PATENTS Number Name Date 1,230,581 Johnson June 19, 1917 1,665,434 Bennett Apr. 10, 1928 1,822,221 Jones Sept. 8, 1931 1,912,381 Meston June 6, 1933 2,323,405 Lindroth' July 6, 1943 FOREIGN. PATENTS Number Country Date 55,275 Australia' Sept. 10, 1912 465,897 Great Britain May 14, 1937 

